Andrew Guthrie scite author profile

Superconducting quantum devices offer numerous applications, from electrical metrology and magnetic sensing to energy-efficient high-end computing and advanced quantum information processing. The key elements of quantum circuits are (single and double) Josephson junctions controllable either by electric current or magnetic field. The voltage control, commonly used in semiconductor-based devices via the electrostatic field effect, would be far more versatile and practical. Hence, the field effect recently reported in superconducting devices may revolutionise the whole field of superconductor electronics provided it is confirmed. Here we show that the suppression of the critical current attributed to the field effect, can be explained by quasiparticle excitations in the constriction of superconducting devices. Our results demonstrate that a miniscule leakage current between the gate and the constriction of devices perfectly follows the Fowler-Nordheim model of electron field emission from a metal electrode and injects quasiparticles with energies sufficient to weaken or even suppress superconductivity.

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Probing superfluid He4 with high-frequency nanomechanical resonators down to millikelvin temperatures

Guénault

Guthrie

Haley

et al. 2019

Phys. Rev. B

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Superfluids, such as superfluid 3 He and 4 He, exhibit a broad range of quantum phenomena and excitations which are unique to these systems. Nanoscale mechanical resonators are sensitive and versatile force detectors with the ability to operate over many orders of magnitude in damping. Using nanomechanical-doubly clamped beams of extremely high quality factors (Q > 10 6 ), we probe superfluid 4 He from the superfluid transition temperature down to mK temperatures at frequencies up to 11.6 MHz. Our studies show that nanobeam damping is dominated by hydrodynamic viscosity of the normal component of 4 He above 1 K. In the temperature range 0.3 − 0.8 K, the ballistic quasiparticles (phonons and rotons) determine the beams' behavior. At lower temperatures, damping saturates and is determined either by magnetomotive losses or acoustic emission into helium. It is remarkable that all these distinct regimes can be extracted with just a single device, despite damping changing over six orders of magnitude. arXiv:1907.00970v1 [cond-mat.mes-hall] 1 Jul 2019

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Nanoscale real-time detection of quantum vortices at millikelvin temperatures

et al. 2021

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Since we still lack a theory of classical turbulence, attention has focused on the conceptually simpler turbulence in quantum fluids. Reaching a better understanding of the quantum case may provide additional insight into the classical counterpart. That said, we have hitherto lacked detectors capable of the real-time, non-invasive probing of the wide range of length scales involved in quantum turbulence. Here we demonstrate the real-time detection of quantum vortices by a nanoscale resonant beam in superfluid 4He at 10 mK. Essentially, we trap a single vortex along the length of a nanobeam and observe the transitions as a vortex is either trapped or released, detected through the shift in the beam resonant frequency. By exciting a tuning fork, we control the ambient vortex density and follow its influence on the vortex capture and release rates demonstrating that these devices are capable of probing turbulence on the micron scale.

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Detecting a phonon flux in superfluid He4 by a nanomechanical resonator

et al. 2020

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Nanoscale mechanical resonators are widely utilized to provide high sensitivity force detectors.Here we demonstrate that such high quality factor resonators immersed in superfluid 4 He can be excited by a modulated flux of phonons. A nanosized heater immersed in superfluid 4 He acts as a source of ballistic phonons in the liquid -"phonon wind". When the modulation frequency of the phonon flux matches the resonance frequency of the mechanical resonator, the motion of the latter can be excited. This ballistic thermomechanical effect can potentially open up new types of experiments in quantum fluids.

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Solid-state instrumentation for use with optical-fibre chemical-sensors

Guthrie¹

1988

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Andrew Guthrie

On the origin of the controversial electrostatic field effect in superconductors

Probing superfluid He4 with high-frequency nanomechanical resonators down to millikelvin temperatures

Nanoscale real-time detection of quantum vortices at millikelvin temperatures

Detecting a phonon flux in superfluid He4 by a nanomechanical resonator

Solid-state instrumentation for use with optical-fibre chemical-sensors

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